Apparatus and methods for restoring power cell functionality in multi-cell power supplies

ABSTRACT

A method is provided for operating a multi-cell power supply that includes multiple series-connected power cells in each of multiple legs. Each power cell includes a bypass device that may be used to selectively bypass and de-bypass the power cell. After a first power cell faults and is bypassed as a result of the fault, the method includes de-bypassing the first power cell without stopping the multi-cell power supply if the first power cell fault was caused by a predetermined operating condition. Numerous other aspects are provided.

REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/695,023, filed Aug. 30, 2012, which is incorporated by reference herein in its entirety for all purposes.

BACKGROUND

This invention relates to multi-cell power supplies. More particularly, this invention relates to apparatus and methods for restoring power cell functionality in multi-cell power supplies.

SUMMARY

In a first aspect of the invention, a method is provided for operating a multi-cell power supply that includes multiple series-connected power cells in each of multiple legs. Each power cell includes a bypass device that may be used to selectively bypass and de-bypass the power cell. After a first power cell faults and is bypassed as a result of the fault, the method includes de-bypassing the first power cell without stopping the multi-cell power supply if the first power cell fault was caused by a predetermined operating condition.

In a second aspect of the invention, a multi-cell power supply is provided that includes multiple series-connected power cells in each of multiple legs, and a controller. Each power cell includes a bypass device that may be used to selectively bypass and de-bypass the power cell. A first power cell faults and is bypassed as a result of the fault. The controller is configured to de-bypass the first power cell without stopping the multi-cell power supply if the first power cell fault was caused by a predetermined operating condition.

Other features and aspects of the present invention will become more fully apparent from the following detailed description, the appended claims and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Features of the present invention can be more clearly understood from the following detailed description considered in conjunction with the following drawings, in which the same reference numerals denote the same elements throughout, and in which:

FIG. 1 is a block diagram of an example multi-cell power supply in accordance with this invention;

FIG. 2A is a block diagram of an example power cell in accordance with this invention;

FIG. 2B is another block diagram of the example power cell of FIG. 2A;

FIGS. 3A-3B are example voltage diagrams of an array of series-connected power cells in accordance with this invention;

FIG. 4A is a flow diagram of an example method in accordance with this invention for determining if a previously bypassed power cell may be de-bypassed;

FIG. 4B is a flow diagram of an alternative example method in accordance with this invention for determining if a previously bypassed power cell may be de-bypassed;

FIG. 5 is an another example voltage diagram of an array of series-connected power cells in accordance with this invention;

FIG. 6 is an example de-bypass method in accordance with this invention;

FIG. 7A is an example voltage diagram of an array of series-connected power cells in which a first power cell is de-bypassed in accordance with this invention;

FIG. 7B is an example voltage diagram of an array of series-connected power cells in which a second power cell is de-bypassed in accordance with this invention;

FIG. 7C is an example voltage diagram of an array of series-connected power cells in which a third power cell is de-bypassed in accordance with this invention; and

FIGS. 8A-8G3 are example values of leg-to-leg phase relationships for multi-cell power supplies in accordance with this invention.

DETAILED DESCRIPTION

Apparatus and methods in accordance with this invention determine if a previously bypassed power cell of a multi-cell power supply may be de-bypassed. If the previously bypassed power cell may be de-bypassed, apparatus and methods in accordance with this invention de-bypass the previously bypassed power cell without stopping the multi-cell power supply.

Multi-cell power supplies, such as described in Hammond U.S. Pat. No. 5,625,545 (the “'545 patent”), Aiello et al. U.S. Pat. No. 6,014,323, Hammond U.S. Pat. No. 6,166,513, Rastogi et al. U.S. Pat. No. 7,508,147, and Hammond et al. U.S. Pat. No. 8,169,107, each of which is incorporated by reference herein in its entirety for all purposes, use modular power cells to deliver medium-voltage power to a load, such as a three-phase AC motor.

As used herein, a “medium voltage” is a voltage of greater than about 690V and less than about 69 kV, and a “low voltage” is a voltage less than about 690V. Persons of ordinary skill in the art will understand that other voltage levels may be specified as “medium voltage” and “low voltage.” For example, in some embodiments, a “medium voltage” may be a voltage between about 1 kV and about 69 kV, and a “low voltage” may be a voltage less than about 1 kV.

Referring now to FIG. 1, an example multi-cell power supply 10 in accordance with this invention is described. Multi-cell power supply 10 includes a transformer 14, a power circuit 16, and a controller 18. Multi-cell power supply 10 receives three-phase power from an AC source, and delivers three-phase power to a load 12 (e.g., a three-phase AC motor, or other similar load). Persons of ordinary skill in the art will understand that multi-cell power supplies in accordance with this invention may be used with AC sources that provide more or less than three power phases, and may deliver more or less than three power phases to load 12. In addition, persons of ordinary skill in the art will understand that multi-cell power supplies in accordance with this invention may include additional, fewer or different components than the ones shown in FIG. 1.

Transformer 14 may be a multiple winding three-phase isolation transformer, such as described in the '545 patent. Such a transformer may have a primary winding which is star or mesh connected, and which is energized from the three-phase AC Source. The transformer may then energize a number of single or multi-phase secondary windings. In example embodiments of this invention, transformer 14 includes a number of secondary windings, each corresponding to a respective power cell in power circuit 16. Persons of ordinary skill in the art will understand that other transformer configurations may be used, and that in some applications an isolation transformer need not be used.

As shown in FIG. 1, transformer 14 is coupled to power circuit 16, which includes fifteen power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5, which are configured to provide medium voltage output power on three output phases (also referred to herein as “legs”) A, B and C to load 12. Each leg A, B, C is fed by a group of series-coupled power cells 16 a 1, 16 b 1, . . . , 16 c 5.

In particular, leg A includes five series-coupled power cells 16 a 1, 16 a 2, 16 a 3, 16 a 4 and 16 a 5, leg B includes five series-coupled power cells 16 b 1, 16 b 2, 16 b 3, 16 b 4 and 16 b 5, and leg C includes five series-coupled power cells 16 c 1, 16 c 2, 16 c 3, 16 c 4 and 16 c 5. Persons of ordinary skill in the art will understand that power circuit 16 may include more or less than three legs, and that each leg may include more or less than five power cells.

The output voltage of each leg A, B and C is the sum of the output voltages of the power cells in the leg. For example, if power cells 16 a 1, 16 b 1, . . . , 16 c 5 each have a maximum output voltage magnitude of about 480V, each leg of power circuit 16 can produce a maximum output voltage magnitude of about 2400V above neutral.

As shown in FIG. 1, each of power cells 16 a 1, 16 b 1, . . . , 16 c 5 is coupled to controller 18, which uses current feedback and voltage feedback (not shown) to control the operation of power cells 16 a 1, 16 b 1, . . . , 16 c 5. Controller 18 may be a microprocessor, such as a TMS320F2801 processor by Texas Instruments, Dallas, Tex., a Programmable Gate Array device (such as FPGA from Altera or Xilinx) that can be configured to perform the functions of a processor, or other similar processor or circuit.

Referring now to FIG. 2A, an example power cell (e.g., power cell 16 a 1) in accordance with this invention is described. Power cell 16 a 1 converts a three-phase AC input signal at input terminals φ1 i, φ2 i, φ3 i to a single phase AC output signal at output terminals VP and VN. In particular, power cell 16 a 1 includes a rectifier 20, a DC bus capacitor 22 (which may include capacitors 22 a and 22 b), an inverter 24, a processor 26, a fiber optic interface 28 and a bypass device 30. Persons of ordinary skill in the art will understand that power cells in accordance with this invention may include additional, fewer, or different components than the components illustrated in FIG. 2A. In addition, persons of ordinary skill in the art will understand that power cells in accordance with this invention may include four-quadrant (“4-Q”) power cells, as are known in the art.

Rectifier 20 includes diodes 32 a, 32 b, 32 c and 34 a, 34 b, 34 c coupled to input terminals φ1 i, φ2 i, φ3 i, and converts a three-phase AC input signal to a substantially constant DC voltage coupled to DC bus capacitors 22 a and 22 b. Persons of ordinary skill in the art will understand that DC bus capacitors 22 a and 22 b may include a capacitor bank, and that the specific amount of capacitance necessary depends on each particular application.

Inverter 24 converts the DC voltage across DC bus capacitors 22 a and 22 b to an AC output at inverter output terminals VIP and VIN. Inverter 24 may be a bridge converter that includes semiconductor switches 36 a, 36 b, 36 c and 36 d, and diodes 38 a, 38 b, 38 a and 38 d. Semiconductor switches 36 a, 36 b, 36 c and 36 d may be any suitable switch element, such as isolated-gate bipolar transistors (“IGBTs”), or other similar switch element. Depending on the power level, various solid-state components may be chosen. As shown in FIG. 2A, diodes 38 a, 38 b, 38 a and 38 d are configured across corresponding semiconductor switches 36 a, 36 b, 36 c and 36 d, respectively.

Semiconductor switches 36 a, 36 b, 36 c and 36 d are coupled to processor 26, which uses pulse-width modulation (“PWM”) to selectively apply DC power to inverter outputs VIP and VIN. In such a PWM operation, switches 36 a, 36 b, 36 c and 36 d can be considered either fully ON or fully OFF as they operate. Persons of ordinary skill in the art will understand that inverter 24 may have topologies other than the bridge converter shown in FIG. 2A, and may use control modes other than PWM.

Processor 26 may be coupled to controller 18 via fiber optic interface 28. Processor 26 may be a TMS320F2801 processor, or may be any other similar processor. Fiber optic interface 28 may be an AFBR 2624Z/AFBR 1624Z fiber optic receiver/transmitter pair, or may be any other similar fiber optic interface. Processor 26 may communicate status information regarding power cell 16 a 1 to controller 18, and controller 18 may communicate control signals to processor 26 to control operation of power cell 16 a 1.

Bypass device 30 is coupled between inverter output terminals VIP and VIN and power cell output terminals VP and VN. Bypass device 30 may be a mechanical, electrical, or a combination mechanical and electrical device that may be selectively switched between a first configuration and a second configuration. Bypass device 30 may include a magnetic contactor, a spring-loaded contact, a pair of anti-parallel silicon controlled rectifiers, or a pair of series transistors, such as described in FIG. 1D and the accompanying text of Hammond et al. U.S. Pat. No. 5,986,909 (the “'909 patent”), which is incorporated by reference herein in its entirety for all purposes. Persons of ordinary skill in the art will understand that other circuits and/or devices may be used for bypass device 30.

In the example embodiment shown in FIG. 2A, bypass device 30 includes a first switch S1 and a second switch S2. First switch S1 and second switch S2 may be selectively opened and closed based on control signals (not shown) provided by processor 26. Persons of ordinary skill in the art will understand that alternative embodiments of this invention may include a bypass device that uses a single switch. As shown in FIG. 2A, bypass device 30 is in a first configuration, with first switch S1 closed and second switch S2 open, and inverter output terminals VIP and VIN coupled to power cell output terminals VP and VN, respectively. In the first configuration, current is conducted by power cell 16 a 1, and power cell 16 a 1 is “not-bypassed.”

In contrast, FIG. 2B illustrates bypass device 30 in a second configuration, with first switch S1 open and second switch S2 closed, forming a shunt path between output terminals VP and VN of power cell 16 a 1. In the second configuration, current is conducted through bypass device 30 instead of power cell 16 a 1, and power cell 16 a 1 is “bypassed.” Thus, bypass device 30 may be used to selectively bypass and not-bypass (or “de-bypass”) power cell 16 a.

Referring again to FIG. 1, during normal operation, each of power cells 16 a 1, 16 a 2, 16 a 3, . . . 16 c 4, and 16 c 5 is operational and not bypassed, and the output voltage of each leg A, B, C is the sum of the output voltages of all five power cells in the leg. For example, FIG. 3A illustrates an array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . 16 c 4, and 16 c 5 that illustrate the voltages from each leg and the phase displacement between legs. In this illustrated example, each power cell 16 a 1, 16 a 2, 16 a 3, . . . 16 c 4, and 16 c 5 is capable of generating an AC output voltage of 480V. Persons of ordinary skill in the art will understand that power cell 16 a 1, 16 a 2, 16 a 3, . . . 16 c 4, and 16 c 5 may provide other AC output voltages.

In the illustrated drawing, each power cell 16 a 1, 16 a 2, 16 a 3, . . . 16 c 4, and 16 c 5 is represented by a circle, with five cells connected in each leg between neutral point N and the respective points A, B and C. As shown, such a multi-cell power supply can typically generate up to approximately 2400V from point N to each of points A, B and C. If controller 18 makes these three voltages equal in magnitude and mutually phase displaced by 120°, then the array will produce a balanced three-phase AC output voltage. In this case, the maximum available line-to-line output voltage (e.g., VAC, VBA, VCB) from the array shown in FIG. 3A is 4160V.

From time to time one or more of power cells 16 a 1, 16 a 2, 16 a 3, . . . 16 c 4, and 16 c 5 may fault, and the faulted power cells may be bypassed, e.g., using the corresponding bypass device 30 shown in FIGS. 2A-2B. Under such circumstances, the voltages from point N to each of points A, B and C typically will no longer be equal in magnitude. For example, if power cells 16 a 4 and 16 a 5 in FIG. 3A fault and are bypassed, but all other power cells are fully functional, leg A can produce a maximum output voltage magnitude of only about 1440V above neutral, whereas legs B and C still can produce a maximum output voltage magnitude of about 2400V above neutral.

As is known in the art, various techniques may be used to reconfigure the operation of multi-cell power supply 10 when one or more power cells are bypassed. For example, the '909 patent describes methods for reconfiguring the operation of a multi-cell power supply such that all not-bypassed power cells may be used to contribute to a balanced output voltage. In particular, by temporarily inhibiting normal operation of the multi-cell power supply, modifying the phase angles between phases A, B and C, and resuming operation of the multi-cell power supply using the modified phase angles, all not-bypassed power cells can be used to provide line-to-line voltages VAC, VBA, VCB having equal magnitudes, and having a mutual phase displacement of 120° between VAC, VBA, and VCB.

For example, as shown in FIG. 3B, if power cells 16 a 4 and 16 a 5 fault and are bypassed, but all other power cells remain fully functional, the phase angle between phases B and C may be reduced to 95°, and the phase angles between phases A and C and between A and B may be increased to 132.5°, which will produce line-to-line voltages VAC, VBA, and VCB having equal magnitudes of 3542V, and a mutual phase displacement of 120° between VAC, VBA, and VCB.

Although multi-cell power supplies may remain operational with some power cells bypassed, it is preferable that all power cells be restored to service. In some instances, a power cell may be bypassed as a result of a temporary operating condition (e.g., a momentary ambient temperature increase) that causes a power cell to fault. If the power cell is otherwise healthy, and if the operating condition that triggered the fault no longer exists, it is preferable to de-bypass the previously bypassed power cell.

Conventionally, bypassed power cells could be de-bypassed only by stopping the multi-cell power supply (and thereby completely shutting down power to and halting operation of the load), disengaging the bypass in the affected power cells, and then restarting the multi-cell power supply. Such stopping and restarting procedures are time consuming, however, and negatively impact the efficiency of equipment and processes being driven by the load.

In accordance with this invention, under certain predetermined circumstances, previously bypassed power cells of a multi-cell power supply may be de-bypassed without stopping the multi-cell power supply. In particular, a previously bypassed power cell may be tested to determine if: (a) the operating condition that caused the power cell fault is one of a predetermined number of operating conditions, (b) the operating condition no longer exists, and/or (c) the bypassed power cell is otherwise functional. Based on the test results, the previously bypassed power cell may be de-bypassed. As described in more detail below, in accordance with this invention, the previously bypassed power cell may be de-bypassed without stopping the multi-cell power supply.

Referring now to FIG. 4A, an example method 50 of this invention is described for determining whether one or more of previously bypassed power cells 16 a 1, 16 a 2, 16 a 3, . . . 16 c 4, and 16 c 5 may be de-bypassed. Method 50 may be implemented in hardware, software or a combination of hardware and software, such as on controller 18, or other processor.

FIG. 5 will be used to illustrate the operation of method 50. In particular, FIG. 5 illustrates an array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5 in which power cells 16 b 4, 16 c 3 and 16 c 5 have previously faulted and are bypassed (e.g., bypass devices 30 b 4, 30 c 3 and 30 c 5 of power cells 16 b 4, 16 c 3 and 16 c 5, respectively, are all engaged), all remaining power cells are operational, and the phase angles between phases A, B and C, have been adjusted to provide line-to-line voltages VAC, VBA, VCB having equal magnitudes of 3249V, and having a mutual phase displacement of 120° between VAC, VBA, and VCB.

Referring again to FIG. 4A, beginning at step 52, a faulted and bypassed power cell (e.g., power cell 16 b 4) is queried to determine if the power cell can report the operating conditions that caused the fault. For example, processor 26 of power cell 16 b 4 may monitor a variety of operating conditions (e.g., DC bus voltage, operating temperature(s), input voltage, input current, IGBT state, arc detection, or other similar operating conditions) of power cell 16 b 4, and may report the operating conditions via fiber optic interface 28 in response to a query from controller 18.

Based on the response to the query, controller 18 determines if the bypassed power cell experienced one or more predetermined operating conditions that caused the power cell fault. For example, at steps 54 a-54 d, controller 18 determines if the reported operating conditions indicate that power cell 16 b 4 experienced an overvoltage fault, an over-temperature fault, a line fault, or a random fault, respectively.

An overvoltage fault may be indicated if the DC bus voltage of power cell 16 b 4 exceeds a predetermined threshold. An over-temperature fault may be indicated if a monitored temperature of power cell 16 b 4 exceeds a predetermined threshold. For 4-Q power cells, a line fault may be indicated if excessive input current existed due to a line dip. A random fault may be any fault condition other than the specific fault conditions identified above. Persons of ordinary skill in the art will understand that controller 18 may determine if the reported operating conditions indicate that the faulted power cell experienced additional, fewer or alternative fault conditions than the predetermined faults described above.

Thus, at step 54 a, if the reported operating conditions indicate that power cell 16 b 4 experienced an overvoltage fault, the process proceeds to step 56 a, and controller 18 determines if the overvoltage fault was the result of regeneration. If multi-cell power supply 10 absorbs regenerative power from load 12, the DC bus voltage of all non-bypassed power cells increases. As a result, the most sensitive power cell will fault (e.g., power cell 16 b 4).

When such an overvoltage fault occurs, multi-cell power supply 10 will temporarily inhibit normal operation, bypass faulted power cell 16 b 4, modify the phase angles between phases A, B and C, and resume operation of multi-cell power supply 10 (assuming that the remaining non-bypassed power cells do not similarly experience an overvoltage fault) using the modified phase angles as described above. While multi-cell power supply 10 is temporarily inhibited, the remaining non-bypassed power cells will cease acceptance of regenerative power, which will cause the DC bus voltage to drop. Multi-cell power supply 10 will resume operation, but faulted power cell 16 b 4 remains bypassed.

If such an overvoltage fault was not a result of a defective power cell (e.g., one that should remain bypassed until it can be replaced), but instead resulted because multi-cell power supply 10 absorbed regenerative power from load 12, bypassed power cell 16 b 4 may be de-bypassed.

Thus, at step 56 a, controller 18 determines if multi-cell power supply 10 absorbed regenerative power from load 12 prior to the overvoltage fault of power cell 16 b 4. For example, controller 18 may query all other non-bypassed power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 2, and 16 c 4 to determine if those power cells also experienced increased DC bus voltages prior to the fault of power cell 16 b 4. Alternatively, or additionally, controller 18 may determine if multi-cell power supply 16 absorbed power from load 12 prior to the fault on power cell 16 b 4.

If either or both tests indicated that multi-cell power supply 10 absorbed regenerative power from load 12 prior to the overvoltage fault of power cell 16 b 4, the process proceeds to step 58 to de-bypass power cell 16 b 4. If one or both test fail to indicate regeneration, the process proceeds to step 60 to continue bypassing power cell 16 b 4.

Referring again to step 54 a, if the reported operating conditions indicate that power cell 16 b 4 did not experience an overvoltage fault, the process proceeds to step 54 b, and controller 18 determines if the reported operating conditions indicate that power cell 16 b 4 experienced an over-temperature fault.

If multi-cell power supply 10 temporarily overheats, the most sensitive power cell typically will fault (e.g., power cell 16 b 4). As a result, multi-cell power supply 10 will temporarily inhibit normal operation, bypass faulted power cell 16 b 4, modify the phase angles between phases A, B and C, and resume operation of multi-cell power supply 10 (assuming that the remaining non-bypassed power cells do not experience an over-temperature fault) using the modified phase angles as described above.

If such an over-temperature fault was not a result of a defective power cell (e.g., one that should remain bypassed until it can be replaced), but instead resulted because multi-cell power supply 10 temporarily overheated, and if power cell 16 b 4 has subsequently cooled, bypassed power cell 16 b 4 may be de-bypassed.

Thus, at step 56 b, controller 18 determines if multi-cell power supply 10 temporarily overheated prior to the over-temperature fault of power cell 16 b 4. For example, controller 18 may query all of the power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 2, and 16 c 4 to determine if the power cells experienced an increase in temperature prior to the fault of power cell 16 b 4, and are no longer at an increased operating temperature.

If the test indicates that multi-cell power supply 10 temporarily overheated prior to the over-temperature fault of power cell 16 b 4, and that all power cells are no longer at an increased operating temperature, the process proceeds to step 58 to de-bypass power cell 16 b 4. If the test fails to indicate temporary overheating, the process proceeds to step 60 to continue bypassing power cell 16 b 4.

Referring again to step 54 b, if the reported operating conditions indicate that power cell 16 b 4 did not experience an over-temperature fault, the process proceeds to step 54 c, and controller 18 determines if the reported operating conditions indicate that power cell 16 b 4 experienced a line fault.

If a line disturbance occurs on the AC Source that drives multi-cell power supply 10, the most sensitive power cell typically will fault (e.g., power cell 16 b 4). As a result, multi-cell power supply 10 will temporarily inhibit normal operation, bypass faulted power cell 16 b 4, modify the phase angles between phases A, B and C, and resume operation of multi-cell power supply 10 (assuming that the remaining non-bypassed power cells do not similarly experience a line fault) using the modified phase angles as described above.

If such a line fault was not a result of a defective power cell (e.g., one that should remain bypassed until it can be replaced), but instead resulted because multi-cell power supply 10 experienced a temporary line disturbance, bypassed power cell 16 b 4 may be de-bypassed.

Thus, at step 56 c, controller 18 determines if multi-cell power supply 10 experienced a temporary line disturbance prior to the line fault of power cell 16 b 4. For example, controller 18 may monitor the input current, input voltage and/or input power flow to multi-cell power supply 10 to check for excursions prior to the fault of power cell 16 b 4.

If the test indicates that prior to the fault of power cell 16 b 4, the input voltage varied greatly from nominal, or the input current changed by more than what could be produced by a single power cell, or if the input power changed by more than what could be produced by a single power cell, the process proceeds to step 58 to de-bypass power cell 16 b 4. If the test fails to indicate such input current, input voltage or input power excursions, the process proceeds to step 60 to continue bypassing power cell 16 b 4.

Referring again to step 54 c, if the reported operating conditions indicate that power cell 16 b 4 did not experience a line disturbance, the process proceeds to step 54 d, and controller 18 determines if power cell 16 b 4 experienced a temporary random fault, but is otherwise functional. If the fault of power cell 16 b 4 was not a result of a defective power cell (e.g., one that should remain bypassed until it can be replaced), but instead resulted from some random reason, bypassed power cell 16 b 4 may be de-bypassed.

Thus, at step 56 d, controller 18 determines if power cell 16 b 4 is functional. For example, while power cell 16 b 4 remains bypassed, controller 18 may test the voltage blocking capability of semiconductor switches 36 a, 36 b, 36 c and 36 d of inverter 24 of power cell 16 b 4 to determine if the switches are functioning properly.

For example, referring to FIG. 2A, a resistor and opto-coupler (not shown) may be placed in parallel with each of semiconductor switches 36 a, 36 b, 36 c and 36 d to monitor the voltage across each switch. Controller 18 (via processor 26) may then turn OFF each of semiconductor switches 36 a, 36 b, 36 c and 36 d to determine if all four switches effectively block voltage, and then individually turn ON semiconductor switches 36 a, 36 b, 36 c and 36 d to determine if each switch conducts when requested.

Referring again to FIG. 4A, if all semiconductor switches 36 a, 36 b, 36 c and 36 d block voltage when turned OFF, and conduct current when turned ON, the process proceeds to step 58 to de-bypass power cell 16 b 4. If the test indicates that any of semiconductor switches 36 a, 36 b, 36 c and 36 d fail to properly turn OFF and ON, the process proceeds to step 60 to continue bypassing power cell 16 b 4.

Following steps 58 and 60, the process proceeds to step 62 to determine if any additional power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 2, and 16 c 4 have been bypassed (e.g., power cells 16 c 3 and 16 c 5 in FIG. 5). If additional power cells have been bypassed, the process returns to step 52, and determines if the additional faulted power cell experienced one or more predetermined fault conditions.

Persons of ordinary skill in the art will understand that the sequence of steps 54 a-54 d may be rearranged in any sequence. In addition, persons of ordinary skill in the art will understand that example processes in accordance with this invention may test more than one faulted power cell at a time, and may de-bypass more than one faulted power cell at a time.

In addition, as shown in FIG. 4B, in an alternative example process 50′, step 56 d (determining if all semiconductor switches 36 a, 36 b, 36 c and 36 d block voltage when turned OFF, and conduct current when turned ON) may be implemented in all instances prior to de-bypassing a power cell without stopping multi-cell power supply 10. This may serve as an additional safeguard to confirm that power cells that have faulted as a result of regeneration, temporary over-heating and/or line disturbances may safely be de-bypassed.

As described above in FIGS. 4A and 4B, at step 58, a previously bypassed power cell may be de-bypassed. Referring now to FIG. 6, an example process 70 in accordance with this invention is described for de-bypassing a previously bypassed power cell without stopping multi-cell power supply 10.

Beginning at step 72, the operation of multi-cell power supply 10 is temporarily inhibited. For example, referring to FIGS. 1 and 2, controller 18 may inhibit operation of multi-cell power supply 10 by inhibiting gating signals to semiconductor switches 36 a, 36 b, 36 c and 36 d of each inverter 24 of each of power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5. By doing so, semiconductor switches 36 a, 36 b, 36 c and 36 d of multi-cell power supply 10 stop switching, and no voltage is supplied to load 12 by multi-cell power supply 10.

Referring again to FIG. 6, at step 74, bypass device 30 of the faulted power cell (e.g., power cell 16 b 4) is reconfigured to de-bypass power cell 16 b 4, thus reconfiguring the array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5. For example, FIG. 7A illustrates an array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5 in which bypass device 30 b 4 is reconfigured to de-bypass power cell 16 b 4.

Referring again to FIG. 6, at step 76, modified phase angles between phases A, B and C are determined for the reconfigured array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5. As described in the '909 patent, the required phase angles between phases A, B and C depend on the number of functional power cells in each phase. For example, controller 18 may calculate specific phase angles for each configuration of the array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5. Alternatively, controller 18 may store (e.g., in one or more lookup tables) predetermined phase angle relationships for various configurations of the array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5.

Referring now to FIGS. 8A-8G3, example table values of the leg-to-leg phase relationship for multi-cell power supplies utilizing anywhere from two to eight power cells per leg. In these tables, the legs are assumed to be in a three-phase Y arrangement having legs A, B and C. Each table has been abbreviated to provide the same values without regard to which power cell in a given leg is bypassed. For example, in FIG. 8A, a leg having A cells=1, corresponds to any configuration in which one of the two power cells in a two power cell leg has been bypassed.

In addition, because a bypass condition in a multi-cell power supply results in identical phase relationships without regard to which legs have the number of bypassed power cells, a multi-cell power supply with A=5, B=3 and C=5, is the same as a multi-cell power supply having non-bypassed cells A=5, B=5 and C=3. The tables, therefore, provide an easy reduced form to cover all of these combinations. In the tables, the A cell is always listed as having the most non-bypassed power cells, the B, second most non-bypassed power cells, and C the least non-bypassed power cells. The tables may be used in a microprocessor scheme as lookup tables to determine the proper phase relationship in a power supply having bypassed power cells.

In the tables, the term Vmax % is used to indicate the maximum voltage that would be available under a bypassed condition as a percentage of the normal line-to-line voltage. All of the phase angles are in relationship to the normal A vector in a multi-cell power supply having no bypassed cells. As an example, Aρ is the angle between the A leg in a bypassed mode as compared to the A leg in an un-bypassed mode. All of the angles given are in relation to the vector for the A leg in an un-bypassed mode.

Thus, for example, referring to FIGS. 7A and 8D, with bypass device 30 b 4 reconfigured to de-bypass power cell 16 b 4, multi-cell power supply 10 corresponds to an A=5, B=5 and C=3 configuration, in which Vmax %=85.1, Aρ=12.5°, Bρ=107.5°, and Cρ=240°. Thus, as shown in FIG. 7A, the phase angle between phase A and phase B is (107.5°−12.5°)=95°, the phase angle between phase B and phase C is (240°−107.5°)=132.5°, and the phase angle between phase C and phase A is (372.5°−240°)=132.5°.

Referring again to FIG. 6, at step 78, controller 18 resumes the operation of multi-cell power supply 10. As shown in FIG. 7A, with power cell 16 b 4 de-bypassed, multi-cell power supply 10 provides line-to-line voltages VAC, VBA, VCB having equal magnitudes of 3542V (85.1% of 4160V), and having a mutual phase displacement of 120° between VAC, VBA, and VCB. In this regard, previously bypassed power cell 16 b 4 has been de-bypassed without stopping multi-cell power supply 10.

Persons of ordinary skill in the art will understand that the time required to temporarily inhibit multi-cell power supply 10, de-bypass previously bypassed power cell 16 b 4, determine modified phase angles between phases A, B and C, and resume operation of multi-cell power supply 10 is very brief, e.g., between about 100 ms to about 350 ms, or other similar duration. During this time interval, load 12 rides-through this power interruption due to the inertia of the load. If there is low inertia, load 12 may slow down significantly. However, unlike previous techniques, methods in accordance with this invention do not stop multi-cell power supply 10, which would completely shut down power to and halt operation of load 12.

Example process 70 of FIG. 6 may be repeated with previously bypassed power cell 16 c 3. Thus, at step 72, the operation of multi-cell power supply 10 is inhibited, and at step 74, bypass device 30 of a faulted power cell (e.g., power cell 16 c 3) is reconfigured to de-bypass power cell 16 c 3, thus reconfiguring the array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5. For example, FIG. 7B illustrates an array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5 in which previously bypassed power cell 16 c 3 is de-bypassed.

Referring again to FIG. 6, at step 76, modified phase angles between phases A, B and C are determined for the reconfigured array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5. Referring to FIGS. 7B and 8D, with bypass device 30 c 3 of power cell 16 c 3 reconfigured to de-bypass power cell 16 c 3, multi-cell power supply 10 corresponds to an A=5, B=5 and C=4 configuration, in which Vmax %=92.9, Aρ=6.4°, Bρ=113.6°, and Cρ=240°. Thus, as shown in FIG. 7B, the phase angle between phase A and phase B is (113.6°−6.4°)=107.2°, the phase angle between phase B and phase C is (240°−113.6°)=126.4°, and the phase angle between phase C and phase A is (366.4°−240°)=126.4°.

Referring again to FIG. 6, at step 78, controller 18 resumes the operation of multi-cell power supply 10. As shown in FIG. 7B, with power cell 16 c 3 de-bypassed, multi-cell power supply 10 provides line-to-line voltages VAC, VBA, VCB having equal magnitudes of 3865V (92.9% of 4160V), and having a mutual phase displacement of 120° between VAC, VBA, and VCB. In this regard, previously bypassed power cell 16 c 3 has been de-bypassed without stopping multi-cell power supply 10.

Likewise, example process 70 of FIG. 6 may be repeated with previously bypassed power cell 16 c 5. Thus, at step 72, the operation of multi-cell power supply 10 is inhibited, and at step 74, bypass device 30 of a faulted power cell (e.g., power cell 16 c 5) is reconfigured to de-bypass power cell 16 c 5, thus reconfiguring the array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5. For example, FIG. 7C illustrates an array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5 in which previously bypassed device 30 c 5 of power cell 16 c 5 is reconfigured to de-bypass power cell 16 c 5.

Referring again to FIG. 6, at step 76, modified phase angles between phases A, B and C are determined for the reconfigured array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5. Referring to FIGS. 7C and 8D, with bypass device 30 c 5 of power cell 16 c 5 reconfigured to de-bypass power cell 16 c 5, multi-cell power supply 10 corresponds to an A=5, B=5 and C=5 configuration, in which Vmax %=100, Aρ=0°, Bρ=120°, and Cρ=240°. Thus, as shown in FIG. 7C, the phase angle between phase A and phase B is (120°−0°)=120°, the phase angle between phase B and phase C is (240°−120°)=120°, and the phase angle between phase C and phase A is (360°−240°)=120°.

Referring again to FIG. 6, at step 78, controller 18 resumes the operation of multi-cell power supply 10. As shown in FIG. 7C, with power cell 16 c 5 de-bypassed, multi-cell power supply 10 provides line-to-line voltages VAC, VBA, VCB having equal magnitudes of 4160V (100% of 4160V), and having a mutual phase displacement of 120° between VAC, VBA, and VCB. In this regard, previously bypassed power cell 16 c 5 has been de-bypassed without stopping multi-cell power supply 10.

Persons of ordinary skill in the art will understand that other techniques (e.g., the alternative techniques described in the '909 patent) may be used to determine phase angles between phases A, B and C of the reconfigured array of series-connected power cells 16 a 1, 16 a 2, 16 a 3, . . . , 16 c 4, 16 c 5 so that a previously bypassed power cell may be de-bypassed without stopping multi-cell power supply 10.

The foregoing merely illustrates the principles of this invention, and various modifications can be made by persons of ordinary skill in the art without departing from the scope and spirit of this invention. 

1. A method of operating a multi-cell power supply comprising a plurality of series-connected power cells in each of a plurality of legs, each power cell comprising a bypass device that may be used to selectively bypass and de-bypass the power cell, wherein after a first power cell faults and is bypassed as a result of the fault, the method comprises: de-bypassing the first power cell without stopping the multi-cell power supply if the first power cell fault was caused by a predetermined operating condition.
 2. The method of claim 1, wherein the predetermined operating condition comprises any of an overvoltage condition, an over-temperature condition, and a line disturbance.
 3. The method of claim 1, further comprising determining if the predetermined operating condition no longer exists prior to de-bypassing the first power cell.
 4. The method of claim 1, further comprising determining if the bypassed power cell is functional prior to de-bypassing the first power cell.
 5. The method of claim 1, wherein each of the legs is connected between a node and a respective line, and the multi-cell power supply comprises line-to-line voltage outputs between pairs of the legs, and wherein the method further comprises: controlling the plurality of power cells to maximize the line-to-line voltage outputs and maintaining the line-to-line voltage outputs substantially equal in magnitude.
 6. The method of claim 5, further comprising substantially balancing a line-to-line phase.
 7. The method of claim 5, wherein maintaining the line-to-line voltage outputs substantially equal in magnitude comprises adjusting leg-to-leg phase relationships.
 8. The method of claim 7, wherein adjusting comprises calculating leg-to-leg phase angles to produce substantially balanced line-to-line voltages.
 9. The method of claim 7, wherein adjusting comprises using predetermined angles based upon a number of faulted cells in each of the legs.
 10. The method of claim 9, wherein the predetermined angles are obtained from tables of values.
 11. A multi-cell power supply comprising: a plurality of series-connected power cells in each of a plurality of legs, each power cell comprising a bypass device that may be used to selectively bypass and de-bypass the power cell; a first power cell that faults and is bypassed as a result of the fault; and a controller configured to de-bypass the first power cell without stopping the multi-cell power supply if the first power cell fault was caused by a predetermined operating condition.
 12. The multi-cell power supply of claim 11, wherein the predetermined operating condition comprises any of an overvoltage condition, an over-temperature condition, and a line disturbance.
 13. The multi-cell power supply of claim 11, wherein the controller determines if the predetermined operating condition no longer exists prior to de-bypassing the first power cell.
 14. The multi-cell power supply of claim 11, wherein the controller determines if the bypassed power cell is functional prior to de-bypassing the first power cell.
 15. The multi-cell power supply of claim 11, wherein each of the legs is connected between a node and a respective line, and the multi-cell power supply comprises line-to-line voltage outputs between pairs of the legs, and wherein the controller controls the plurality of power cells to maximize the line-to-line voltage outputs and maintain the line-to-line voltage outputs substantially equal in magnitude.
 16. The multi-cell power supply of claim 15, wherein the controller substantially balances a line-to-line phase.
 17. The multi-cell power supply of claim 15, wherein the controller adjusts leg-to-leg phase relationships to maintain the line-to-line voltage outputs substantially equal in magnitude.
 18. The multi-cell power supply of claim 17, wherein the controller calculates leg-to-leg phase angles to produce substantially balanced line-to-line voltages.
 19. The multi-cell power supply of claim 17, wherein the controller adjusts leg-to-leg phase relationships by using predetermined angles based upon a number of faulted cells in each of the legs.
 20. The multi-cell power supply of claim 19, wherein the controller obtains the predetermined angles from tables of values. 